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Speed Control of Universal Motor Using Sniversal Bridge Mr NOVATEUR PUBLICATIONS INTERNATIONAL JOURNAL OF INNOVATIONS IN ENGINEERING RESEARCH AND TECHNOLOGY [IJIERT] ISSN: 2394-3696 VOLUME 5, ISSUE 4, Apr-2018 SPEED CONTROL OF UNIVERSAL MOTOR USING SNIVERSAL BRIDGE MR. P. P. KULKARNI Electrical Department, Sanjeevan Engineering Institute and Technology, Panhala, Kolhapur. India. BARALE RENU Electrical Department, Sanjeevan Engineering Institute and Technology, Panhala, Kolhapur. India. POTE TEJASHREE Electrical Department, Sanjeevan Engineering Institute and Technology, Panhala, Kolhapur. India. SUTAR KOMAL Electrical Department, Sanjeevan Engineering Institute and Technology, Panhala, Kolhapur. India. POWAR VAISHALI Electrical Department, Sanjeevan Engineering Institute and Technology, Panhala, Kolhapur. India. ABSTRACT Speed control of AC and DC motor is carried out by using universal bridge drive. This universal Bridge which consist combination of IGBT & MOSFET and Diodes by changing the gate pulses. This universal Bridge is controlled by V/F control method. This method is used for single phase AC and DC motor control with small modification in hardware and software using Simulink. Power circuit includes inverter which connected to PWM generator. There are many industrial and domestic applications were speed variation is required, many speed control techniques are used like rheostat control, variable voltage control, v/f control. The simulation is carried out in MATLAB. The characteristics of motors can be studied from waveform obtained by simulation. INTRODUCTION In electrical drives we have various speed control methods to control speed of 1ᴓ and 3ᴓ AC and DC motors. For speed controlling of motors we use separate bridge circuits such as rectifier and inverter circuit which include power electronic devices. The rectifier circuit controls speed of AC motor and inverter circuit controls speed of DC motor. To overcome this problem we have created a single bridge which acts as rectifier as well as inverter and controls speed of AC as well as DC motor. This single bridge circuit includes combination of MOSFET’s and SCR’s, where MOSFET’s are voltage controlling devices hence this are used to form inverter bridge circuit and SCR’s are current controlling devices hence this are used to form rectifier bridge circuit. Fig.1. Block Diagram 22 | P a g e NOVATEUR PUBLICATIONS INTERNATIONAL JOURNAL OF INNOVATIONS IN ENGINEERING RESEARCH AND TECHNOLOGY [IJIERT] ISSN: 2394-3696 VOLUME 5, ISSUE 4, Apr-2018 I. HARDWARE IMPLEMENTATION A. POWER SUPPLY CIRCUIT Smoothing Regulator Transformer Rectifier Fig.2. Block Diagram of power supply The power supply circuit consists of step down transformer 230/12V which is passed through single phase bridge rectifier. The rectifier converts the alternating current (AC to DC) and capacitor filters are used for smoothing out the DC. The above fig. shows the block diagram of power supply circuit. B. CONTROL CIRCUIT The control circuit consists of microcontroller-Arduino Pro Mini w/ATMega328, MOSFET’s and SCR’s and circuit is controlled by gate signal. The microcontroller circuit requires +5V DC supply. The 12 V from the 230/12V step down transformer is rectified and a constant voltage of 5V DC is obtained with the help of voltage regulator. The switching schemes to the metal oxide semiconductor field effect transistor (MOSFET)are generated by microcontroller. This microchip is controller circuit that is used to generate the modulated and carrier signal for the inverter. For generation of modulating output for inverter the zero crossing detector (ZCD). The schematic of the control circuit is, Fig.3. MOSFET Driver Fig.4. SCR Driver 23 | P a g e NOVATEUR PUBLICATIONS INTERNATIONAL JOURNAL OF INNOVATIONS IN ENGINEERING RESEARCH AND TECHNOLOGY [IJIERT] ISSN: 2394-3696 VOLUME 5, ISSUE 4, Apr-2018 C. DRIVER CIRCUIT The driver circuit consists of universal bridge which consists combination of MOSFET’s, SCR’s driving the gate signal. The driver consists of optocoupler-4N33 which isolates electrical signals. The driver also consists of IC-IR211D which acts as gate drive. The below fig, shows schematic of driver circuit, Fig.5. Diver Circuit D. MICROCONTROLLER (Ardunio Pro Mini ATmega w/328) Fig.6 Pin digram of ArdunioProMini The Ardunio Pro is microcontroller board based on the ATmega328. The Pro comes in 5V/16MHz. It has 14 digit input/output pins, 6 analog inputs, a battery power jack, a power switch, a rest button, and holes for mounting a power jack, an ICSP header, and pin headers. A six pin header can be connected to an FIDI cable or Sparkfun breakout to provide USB power and communication to the board. The Ardunio Pro is intended for semi-permanent installation in objects or exhibitions. The board comes without pre-mounted headers, allowing the use of various types of connectors or direct soldering of wires. The pin layout is compatible with Ardunio shields. II. RESULT The following tests was conducted in laboratory. 1. DC motor load was connected at the output of inverter and speed was varied by using variable pot. Input voltage 230V AC, Output Voltage 230V, DC motor rating:-230V, 11A, 1500 RPM, 3HP. The variation of speed with armature current is shown in bellow graph: 24 | P a g e NOVATEUR PUBLICATIONS INTERNATIONAL JOURNAL OF INNOVATIONS IN ENGINEERING RESEARCH AND TECHNOLOGY [IJIERT] ISSN: 2394-3696 VOLUME 5, ISSUE 4, Apr-2018 Speed VS Armature Current (DC motor) 120% 100% 80% 60% 40% Speed in % in Speed 20% 0% 2 4 6 8 10 Armature Current Ia Fig.7 Waveform across load at different values of armature current. 2. A Fan load was connected at the output of inverter and speed was varied by using variable pot. Input voltage 230V AC, Output voltage 230V, Induction motor rating:-230V, 1250RPM, 1A, 55W. The variation of speed with current is shown in bellow graph: Speed VS Current (AC motor) 120% 100% 80% 60% 40% Speed in % in Speed 20% 0% 0.2 0.5 0.6 0.7 1 Current in Ampere Fig.7 Waveform across load at different values of current III. CONCLUSION This paper presents variable frequency drive to control the speed of 1ᴓ and 3ᴓ AC and DC motor. The main aim this project is to create a universal control board through which controlled a single or three phase AC and DC motor, with slight software and hardware modification. This universal board can hence used for different kinds of laboratory applications. The designed system was successfully fabricated and tested in the laboratory. AKNOWLADGEMENT The authors are truly grateful to Mr.P.P. Kulkarni and Mr N.S. Jadhav sir for their valuable suggestions in reviewing the manuscript. REFERENCES JOURNAL PAPERS (1) Ranjit Kumar Bindal1,Amandeep Kaur2.Speed Control Of Induction Motor Drive Using Universal Bridge, International Journal for Research in applied Science & Engineering Technology. BOOKS (1) M. H. Rashid, Power electronics (circuits, devices and applications). 25 | P a g e NOVATEUR PUBLICATIONS INTERNATIONAL JOURNAL OF INNOVATIONS IN ENGINEERING RESEARCH AND TECHNOLOGY [IJIERT] ISSN: 2394-3696 VOLUME 5, ISSUE 4, Apr-2018 THESES I. Ismail, S.Taib, A.R Mohdsaad, M. Isa and I, Daut,”Development of control circuit for single phase inverter using Atmel Microcontroller,” II. Thida Win, Nang Sabai, and Hnin Nandar Maung, “Analysis of variable frequency three phase induction motor drive”. III. Mohd Fakhizan bin Ramie, Mohammad Fadhil Pesol, and Khaisul Nisak Md has an, “PWM technique to control speed of induction motor using MATLAB”. IV. Rodolfo Enchilada, Sergio Horta, Marco Oliver, has, “A three phase motor drive using IGBT/MOSFET and constant V/F speed control with slip regulation”.3 26 | P a g e .
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